CN108296460B - A method of continuous casting billet center-line segregation is eliminated using material dilution is increased - Google Patents

Abstract

The present invention relates to a kind of methods for eliminating continuous casting billet center-line segregation using material dilution is increased comprising: acquisition production status parameter；Determine feed speed v_a, increase material thickness d and increase material width w, w > d；Based on standard solute concentration C_MarkIt calculates wick-containing end and is segregated index, obtain solute concentration C_oi, anti-to release the solute concentration C for increasing material_a；According to C_a≤C_Choosing<C_MarkIt obtains choosing concentration C_Choosing, according to increasing material thickness d, increase material width w and choose concentration C_Choosing, select and/or manufacture increase material, will increase that material is continuous, vibration is transported to wick-containing end.The method provided by the invention for eliminating continuous casting billet center-line segregation using material dilution is increased, mitigates using alloying component proportion and eliminates center-line segregation, while increasing material to eliminate center porosity.Increase when material reaches wick-containing end and be completely melt, under effect of vibration, the liquid group of fusing is thoroughly mixed with the casting liquid in wick-containing end；To solve two large inner mass defect of center-line segregation and center porosity in continuous casting billet simultaneously.

Description

A method of continuous casting billet center-line segregation is eliminated using material dilution is increased

Technical field

It is especially a kind of to utilize the side for increasing material dilution elimination continuous casting billet center-line segregation the present invention relates to continuously casting field Method.

Background technique

Continuous casting billet center segregation is with center porosity, while the presence for adding inner clamps sundries can severe exacerbation slab Energy.The floating that the high degree of superheat is cast with conducive to field trash, but center segregation degree can be aggravated, minimize center segregation degree for It is particularly significant to further increase slab quality.

In conventional continuous casting production process, the method that can reduce center segregation used at present has: solidification end Electromagnetic agitation and slighter compress etc..However, all there are some drawbacks in these measures.The position that solidification end applies electromagnetic agitation is difficult to It is accurate to determine, and when being applied to the biggish slab of specification, due to kelvin effect that there are efficiency is lower.Although solidification end simultaneously Slighter compress can closely knit slab division center, but the solute being enriched with can come back to liquid core to constantly accumulating, cannot be from basic Upper elimination center segregation.

Except the above method, existing external open report (Ukraine patent No.40053A) is proposed to continuous casting mold The technology of the interior cold steel band of feeding.The solidification mode that the ecto-entad of slab script is changed using steel belt melting heat absorption, is increased The equiaxial crystal ratio at slab center, closely knit division center, to improve Inner Quality of Billet.The open report in the country (patent: CN200610044356.0, CN201210565960.3, CN201410799131.0) hello carrying device or technology have been carried out generally It introduces, but without proposing specific implementation parameter." a kind of slab CC machine process crystallization device feeds the determination of steel band technological parameter to patent Method " (CN.105033216) describes the parameter determination method of feeding steel band, in the design on the basis of this technology, considers During casting blank solidification the case where soluterich, a kind of skill using increasing material dilution casting blank solidification end center-line segregation is proposed Art.

Summary of the invention

(1) technical problems to be solved

In order to solve the above problem of the prior art, the present invention provides a kind of while eliminating segregation and loose, improvement center The method for eliminating continuous casting billet center-line segregation using material dilution is increased of line alloying component.

(2) technical solution

In order to achieve the above object, the present invention provides a kind of side that continuous casting billet center-line segregation is eliminated using increasing material dilution Method comprising:

S1 acquires continuous casting billet production status parameter；Determine feed speed v_a, and determine and increase material thickness d and increasing material width w, w >d；

S2, the standard solute concentration C based on continuous casting billet solute_Mark, calculate liquid core of continuous casting billet end and be segregated index, obtain wick-containing The solute concentration C of end_o, then the anti-solute least concentration C for releasing increasing material_a；

S3, according to C_a≤C_Choosing<C_MarkIt obtains choosing concentration C_Choosing, according to increasing material thickness d, increase material width w and choose concentration C_Choosing, choosing With and/or manufacture increase material, with feed speed v_aMaterial will be increased and be delivered continuously to the wick-containing end of continuous casting billet, applied to increasing material when conveying Vibration.

Preferably, S1 includes:

The duty parameter of S11, acquisition include at least, depth location H of the wick-containing end in liquid core, pouring temperature T_{It pours}、 The liquidus temperature T of casting molten steel_l, work pulling rate v_c, continuous casting billet sectional dimension and cooling condition；

S12, by fitting formula lnt_m=4.082+2.085lnd-0.497ln Δ T-0.365lnT₀It is completely molten to calculate increasing material Time t needed for changing_m, cast liquid degree of superheat Δ T=T_{It pours}-T_l, increase material thickness d and takes within 1mm to 8mm, T₀It is initially warm to increase material Degree；Again by v_a≤H/t_mObtain feed speed v_a；

S13, byIt obtains increasing material cross-sectional area A_a, wherein C_pFor molten steel specific heat, A_cFor Continuous casting billet sectional area, Q_BFor the cooling heat of continuous casting billet, L is the latent heat of fusion for increasing material；

By A_a=d × w obtains increasing material width w.

Preferably, S2 includes:

S21 redistributes rule according to the solute precipitation in process of setting, calculates liquid core of continuous casting billet end and be segregated index, Obtain the solute concentration C of wick-containing end_o；

S22, byObtain increasing the solute least concentration C of material_a, wherein A_oFor wick-containing The sectional area of end, υ_cFor the pulling rate that works, A_a=d × w.

Further, in S21: including n kind solute in continuous casting billet, the respective standard solute concentration of solute is in n >=1, n C_{Mark i}, i=1 ..., n,；

To C_{Mark i}, cooling boundary condition, continuous casting billet sectional dimension, work pulling rate v_c, viscosity, density, thermal conductivity, diffusion coefficient And distribution coefficient, macromodel is set up, macromodel includes continuity equation, the equation of momentum, energy equation and solute transport Governing equation carries out complete coupled simulation calculating to macromodel, flow field, temperature field and solute Distribution is calculated；

Based on solute balance distribution coefficient, diffusion coefficient, local coagulation's time and pine-tree structure, stream field, temperature field and Solute Distribution carries out micromodel calculating, and micromodel describes the respective solute concentration C of n kind solute using lever model_oi, paste The functional relation of area's liquid fraction and temperature three obtains concentration field, liquidus curve, solidus and the liquid fraction of solidification front；Concentration It include C in_oi。

Further, in S21: further including the impurity concentration C of plurality of impurities when setting up macromodel_{Miscellaneous j}, j=n+1 ..., m, m≥n+1；The impurity concentration C of wick-containing end is calculated by micromodel_oj；

The impurity upper concentration C increased in material is calculated in S22_aj；

S3 also chooses the impurity concentration C increased in material_{Select j}≤C_aj。

Further, in S21: concentration field, liquid fraction and pine-tree structure being returned to macromodel, to the result of macromodel It is modified, then micromodel calculating, the micromodel result optimized is carried out to the result of macromodel.

Preferably, in S3: before increasing material and being added in casting liquid core, to material heating is increased, making to increase material initial temperature T₀ Reach 200 DEG C -500 DEG C.

Preferably, the amplitude of the vibration is less than 3mm, and the frequency of vibration is not less than 100Hz.

Preferably, at the liquid level of liquid core, increase the inlet bit of material setting between the mouth of a river and crystallizer leptoprosopy, and away from the mouth of a river Distance be the mouth of a river and the narrow distance between the surface of crystallizer one third.

Preferably, the increasing material is sent into during liquid core, and the increasing material at liquid level is sent into around position and is protected using gas Shield.

(3) beneficial effect

The present invention provides a kind of method for eliminating continuous casting billet center-line segregation using material dilution is increased, and is matched using alloying component Mitigate and eliminate center-line segregation, while increasing material to eliminate center porosity.When increasing the wick-containing end of material arrival solidification front It is completely melt, and under effect of vibration, the liquid group of fusing is thoroughly mixed with the casting liquid in wick-containing end；Increase material and continuous casting billet Solute possesses concentration difference in itself, therefore is diluted to the solute of center enrichment, to solve center line in continuous casting billet simultaneously Segregation and two large inner mass defect of center porosity.

It first determines and increases material thickness, one, which carrys out this thickness range, facilitates the production for increasing material, can uniformly roll, can preferably keep Increase material consistency of thickness, be on the other hand also convenient for increasing material and effectively melt, after determining the thickness selected, supply speed is calculated Degree.This fitting formula is relatively suitble to the alloy continuous casting based on ferro element, can be used for the other kinds of alloy of approximate calculation and connects Casting process.By the matching of feed speed and increasing material thickness, guarantee that increase material front end is completely melt when reaching wick-containing end.It is subsequent Solid-state increase material constantly transport forward, constantly to wick-containing end conveying liquid increasing material.

Increasing material solute concentration obtained by calculation is more acurrate, is the lower limit of the concentration value specifically used.This formula calculates Increasing material solute concentration value change with the variation for increasing material sectional dimension, convenient for actual use and adjustment, calculate step it is simple, Fast.

Less input parameter is utilized in macromodel and micromodel, enumerates more influence factor, comprehensively accurate Mathematical modeling has been carried out to real process, fast and accurately obtain the solute concentration of wick-containing end, for it is subsequent calculating standard is provided True parameter.

By the adjustment of impurity concentration, continuous casting billet center mass is preferably improved, improves continuous casting billet performance.

The output of micromodel is returned into macromodel and is used as amendment, realize data macro-scale and micro-scale it Between transmission so that model is three-dimensional more preferable, the deviation of given value is smaller.

It is preheated to material is increased, it is possible to reduce the thermal losses in liquid core, and also increasing material can reach faster molten Point.Increase material initial temperature simultaneously also without excessively high, avoids and just melted before reaching wick-containing end.

Small size high-frequency vibration is imposed to material is increased, the liquid group and casting liquid for being conducive to that material fusing will be increased stir evenly.Crystallizer It is sent between leptoprosopy and the mouth of a river and increases material, while increased material and being biased to close to the mouth of a river, more effectively can increase material using liquid core heating.Simultaneously The transport path for increasing material is more stable.

To the application gas shield of material feeding position is increased at liquid level, it can prevent the covering slag on liquid level upper layer from entering with material is increased Liquid core.

Detailed description of the invention

Fig. 1 is a kind of implementation diagram for eliminating the method for continuous casting billet center-line segregation using material dilution is increased；

Fig. 2 is the schematic diagram of a kind of method of macromodel and micromodel that building is interactive.

[description of symbols]

1: the mouth of a river；2: increasing material body；3: liquid core；4: mushy zone；5: solidified shell；D: increase material thickness；D: wick-containing diameter.

Specific embodiment

In order to preferably explain the present invention, in order to understand, with reference to the accompanying drawing, by specific embodiment, to this hair It is bright to be described in detail.

Embodiment 1

As shown in Figure 1, casting liquid is flowed out from the mouth of a river 1, casting liquid is flowed among crystallizer.The side wall of crystallizer is constantly right Liquid core 3 cools down, so that 3 side of liquid core and bottom constantly crystallize, forms mushy zone 4, mushy zone 4 continues cooling and forms solidification Green shell 5.Solidified shell 5 is pulled out from lower part.The constantly flowing of liquid core 3, mushy zone 4 and solidified shell 5 develops, the company of being integrally formed Slab.Under the premise of condition is constant, the boundary on the boundary of liquid core 3 and mushy zone 4, mushy zone 4 and solidified shell 5 is stable It is in certain position, stablizes the shape for keeping certain.

The present embodiment continuous casting billet is low-carbon continuous casting heavy slab, to eliminate the segregation of center line with the following method:

S11, continuous casting billet section A_c=D_c×W_c=220mm × 1800mm.Wick-containing diameter D=30mm, wick-containing end is in liquid phase Depth in cave 3Wherein work pulling rate v_c=0.8m/min, coagulation factor K₂=20.Pouring temperature T_{It pours}=1536 DEG C, crystallizer, secondary cooling zone and the amount of cooling water of air cooling zone summation Q_B=399843J, that is, continuous casting billet cooling heat.The liquid of casting molten steel Liquidus temperature T_l=1516 DEG C, molten steel specific heat at constant pressure C_p=710J/ (kg DEG C), the chemical component and its mass percent of molten steel (wt%) it is as follows:

Code name

CMark 1

CMark 2

CMark 3

CMark 4

CMark 5

CMark 6

Ingredient

C

Si

Mn

Ti

S

P

Molten steel

0.125

0.265

1.41

0.0138

0.00129

0.0112

S12 prepares to choose or manufacture thickness d=3mm, initial temperature T₀When=200 DEG C of increasing material, increases material and be completely melt institute The time t needed_mBy fitting formula lnt_m=4.082+2.085lnd-0.497ln Δ T-0.365lnT₀It determines, wherein casting liquid mistake Temperature Δ T=T_{It pours}-T_l。

Again by v_a≤H/t_mObtain feed speed v_a=0.3m/s.

S13, byIt obtains increasing material cross-sectional area A_a, wherein the latent heat of fusion L for increasing material is 276000J/kg takes the latent heat of fusion for increasing material identical as continuous casting billet at this time, can be returned and be corrected according to structure；

Again by A_a=d × w obtains increasing material width w=10mm.

S21, to the standard solute concentration C of solute each in continuous casting billet_{Mark i}, cooling boundary condition, continuous casting billet sectional dimension, work Make pulling rate v_c, viscosity, density, thermal conductivity, diffusion coefficient and distribution coefficient, set up macromodel, macromodel includes continuity Equation, the equation of momentum, energy equation and solute transport governing equation carry out complete coupled simulation calculating, meter to macromodel Calculation obtains flow field, temperature field and solute Distribution；

Based on solute balance distribution coefficient, diffusion coefficient, local coagulation's time and pine-tree structure, stream field, temperature field and Solute Distribution carries out micromodel calculating, and micromodel describes each solute concentration C using lever model_oi, mushy zone liquid fraction and The functional relation of temperature three obtains concentration field, liquidus curve, solidus and the liquid fraction of solidification front；It include liquid in concentration field The concentration C of core end carbon_o1=0.143wt%；Si, C_o2=0.278wt%；Mn,C_o3=1.49wt%；Ti,C_o4= 0.014wt%；S,C_o5=0.00142wt%；P,C_o6=0.012wt%.

In this step, existing continuous casting billet center can also be sampled, carry out Physico-chemical tests, the solute in detection data is dense Degree can be used as the reference of the result of theoretical calculation.

As shown in Fig. 2, continuity equation and the equation of momentum are established in the flowing to continuous casting billet, energy equation is established to temperature, Solute transport governing equation is established to the concentration of solute.Heat buoyancy caused by temperature can cause the variation of flowing, while solute Element forms thermal diffusion under temperature action；Flowing can bring up thermal convection, and Convention diffusion while also results in solute migration； So that liquidus curve solidus is drifted about, crystallization influences the distribution of temperature, and the density of different solutes is different, causes for the difference of solute concentration Buoyant flow.Complete coupled simulation calculating is carried out to macromodel, obtained data input micromodel.

Pine-tree structure can influence porosity, return to macromodel for correcting flowing.Solutes accumulation causes microsegregation, Macromodel is returned for correcting concentration.

S22, byObtain increasing the solute concentration of material, wherein carbon concentration C_a1 =0.106wt%, wherein A_oFor the sectional area of wick-containing end,

S3 chooses carbon concentration C_{Select 1}=C_a1=0.106wt%, Si, C_{Select 2}=C_a2=0.253wt%；Mn,C_{Select 3}=C_a3 =1.335wt%；Ti,C_{Select 3}=C_a4=0.0136wt%；S,C_{Select 5}=C_a5=0.00116wt%；P,C_{Select 5}=C_a6= 0.0104wt%；D × w=3mm × 10mm manufacture increases material, is preheated to initial temperature T₀=200 DEG C, it is added into liquid core 3.

It is the mouth of a river 1 apart from crystallization as shown in Figure 1, increasing material in the distance at the feeding positional distance mouth of a river 1 on 3 top of liquid core The one third of device side wall distance.The continuous casting billet section of the present embodiment be rectangle, increase material inlet bit be set to crystallizer distance compared with Between narrow two sides.The feeding direction for increasing material is obliquely, to guarantee to increase the wick-containing end that material end reaches liquid core 3.Increase material end End is just heated to fusing when reaching wick-containing end.

During being sent into increasing material, apply amplitude 2.5mm, the vibration of the frequency 350Hz of vibration to material body 2 is increased.Vibration Can be vertical, parallel with feeding direction or intersect in direction.When vertical, direction of vibration is preferably along thickness direction.When parallel, The solid-state for increasing material increases the impact wick-containing end even mushy zone 4 of the meeting frequency low-amplitude of material body 2, smashes pine-tree structure and promotes casting liquid Flowing.Gas shield is applied to the feeding position for increasing material simultaneously, 3 surface of liquid core is blown away and increases the covering slag that material is sent at position, Prevent covering slag from entering liquid core 3 in the case where the increasing material body 2 of high-speed motion drives.

Embodiment 2

Such as the calculated result of embodiment 1, C is chosen_{Select 1}=0.11wt% > C_a1, C_{Select 2}=0.26wt% > C_a2,C_{Select 3}= 1.40wt% > C_a3,C_{Select 4}=0.0137wt% > C_a4,C_{Select 5}=0.0012wt% > C_a5, C_{Select 6}=0.011wt% > C_a6, manufacture increasing material. Element ratio more preferably controls, and increasing material manufacturing is convenient, and technique is simpler.Continuous casting billet center segregation can also greatly be mitigated and solved Center porosity.

Embodiment 3

Such as embodiment 1, impurity concentration C is added in the input of macromodel_{Mark 7}, include C in final output_a7, choose C_{Select 7}<C_a7Manufacture increases material, and increasing material section is annular, and semidiameter is 3mm inside and outside annular, and annulus area is equal to 30mm², increasing material manufacturing It is convenient.During being sent into increasing material, apply amplitude 2mm, the vibration of the frequency 500Hz of vibration to material body 2 is increased.It can be further It improves continuous casting billet center performance and solves center porosity.

Upper embodiment is only presently preferred embodiments of the present invention, for those of ordinary skill in the art, according to the present invention Thought, there will be changes in the specific implementation manner and application range, and this specification should not be construed as to limit of the invention System.

Claims (8)

1. it is a kind of using increase material dilution eliminate continuous casting billet center-line segregation method, which is characterized in that itself the following steps are included:

S1 acquires continuous casting billet production status parameter；Determine feed speed v_a, and determine and increase material thickness d and increasing material width w, w > d； Specifically include following step S11~S13:

The duty parameter of S11, acquisition include at least, depth location H of the wick-containing end in liquid core, pouring temperature T_{It pours}, casting The liquidus temperature T of molten steel_l, work pulling rate v_c, continuous casting billet sectional dimension and cooling condition；

S12, by fitting formula lnt_m=4.082+2.085lnd-0.497ln Δ T-0.365lnT₀Increasing material is calculated to be completely melt Required time t_m, cast liquid degree of superheat Δ T=T_{It pours}-T_l, increase material thickness d and takes within 1mm to 8mm, T₀To increase material initial temperature；

Again by v_a≤H/t_mObtain feed speed v_a；

S13, by

It obtains increasing material cross-sectional area A_a, wherein C_pFor molten steel specific heat, A_cFor continuous casting billet sectional area, Q_BFor the cooling heat of continuous casting billet Amount, L are the latent heat of fusion for increasing material, v_cFor the pulling rate that works, T_lFor the liquidus temperature for being poured molten steel；

By A_a=d × w obtains increasing material width w；

S2, the standard solute concentration C based on continuous casting billet solute_Mark, calculate liquid core of continuous casting billet end and be segregated index, obtain wick-containing end Solute concentration C_o, then the anti-solute least concentration C for releasing increasing material_a；S2 includes the following steps S21~S22:

S21 redistributes rule according to the solute precipitation in process of setting, calculates liquid core of continuous casting billet end and be segregated index, obtain The solute concentration C of wick-containing end_o；

S22, by

Obtain increasing the solute least concentration C of material_a, wherein A_oFor the sectional area of wick-containing end, v_cFor the pulling rate that works, A_a=d × w；

S3, according to C_a≤C_Choosing< C_MarkIt obtains choosing concentration C_Choosing, according to increasing material thickness d, increase material width w and choose concentration C_Choosing, select And/or manufacture increases material, with feed speed v_aMaterial will be increased and be delivered continuously to the wick-containing end of continuous casting billet, apply vibration to increasing material when conveying It is dynamic.

2. the method as described in claim 1 for eliminating continuous casting billet center-line segregation using material dilution is increased, which is characterized in that S21 In: it include n kind solute in continuous casting billet, the respective standard solute concentration of solute is C in n >=1, n_{Mark i}, i=1 ..., n；

To C_{Mark i}, cooling boundary condition, continuous casting billet sectional dimension, work pulling rate v_c, viscosity, density, thermal conductivity, diffusion coefficient and point Distribution coefficient, sets up macromodel, and macromodel includes continuity equation, the equation of momentum, energy equation and solute transport control Equation carries out complete coupled simulation calculating to macromodel, flow field, temperature field and solute Distribution is calculated；

Based on solute balance distribution coefficient, diffusion coefficient, local coagulation's time and pine-tree structure, stream field, temperature field and solute Distribution carries out micromodel calculating, and micromodel describes the respective solute concentration C of n kind solute using lever model_oi, mushy zone liquid The functional relation of one after another and temperature three obtains concentration field, liquidus curve, solidus and the liquid fraction of solidification front；In concentration field Including C_oi。

3. the method as claimed in claim 2 for eliminating continuous casting billet center-line segregation using material dilution is increased, it is characterised in that: S21 In further include when also setting up macromodel plurality of impurities impurity concentration C_{Miscellaneous j}, j=n+1 ..., m, m >=n+1；By micromodel The impurity concentration C of wick-containing end is calculated_oj；

The impurity upper concentration C increased in material is also calculated in S22_aj；

The impurity concentration C increased in material is also chosen in S3_{Select j}≤C_aj。

4. the method as claimed in claim 2 for eliminating continuous casting billet center-line segregation using material dilution is increased, which is characterized in that S21 In: concentration field, liquid fraction and pine-tree structure are returned into macromodel, the result of macromodel is modified, then to macroscopical mould The result of type carries out micromodel calculating, the micromodel result optimized.

5. the method as described in claim 1 for eliminating continuous casting billet center-line segregation using material dilution is increased, which is characterized in that S3 In: before increasing material and being added in casting liquid core, to material heating is increased, make to increase material initial temperature T₀Reach 200 DEG C -500 DEG C.

6. the method as described in claim 1 for eliminating continuous casting billet center-line segregation using material dilution is increased, it is characterised in that: described The amplitude of vibration is less than 3mm, and the frequency of vibration is not less than 100Hz.

7. the method as described in claim 1 for eliminating continuous casting billet center-line segregation using material dilution is increased, it is characterised in that: liquid phase At the liquid level in cave, the inlet bit for increasing material is the mouth of a river setting in the distance between the mouth of a river and crystallizer leptoprosopy, and away from the mouth of a river and crystallizes The one third of the narrow distance between the surface of device.

8. the method as described in claim 1 for eliminating continuous casting billet center-line segregation using material dilution is increased, it is characterised in that: described Increase material to be sent into during liquid core, the increasing material at liquid level, which is sent into around position, uses gas shield.